As @EOF explained, always use `-fno-math-errno`

, and use `-march=native`

if you can, or at least `-msse4`

if you don't need the binary to run on old machines like first-gen Core 2, or AMD Phenom II. (Preferably also other good stuff like `popcnt`

and SSE4.2, like

`-march=nehalem -mtune=haswell`

)

And preferably `-O3`

to enable SIMD auto-vectorization when possible, although that's sometimes *not* possible for floating point, e.g. reductions like dot product or sum of an array, because FP math isn't quite associative.

(`-ffast-math`

will let compilers pretend it is, or you can use `#pragma omp simd reduction(+:my_var_name)`

to give it license to rearrange order of operations in just one loop. But that's not safe in general, e.g. if your code does stuff like Kahan summation to compensate for FP rounding error, and enables other optimizations like treating denormals as 0.)

You can get even better asm out of gfortran / gcc by omitting the `floor()`

. Neither seems to realize that any result of sqrt will be non-negative or NaN, and thus `floor(sqrt) = trunc(sqrt)`

(Related: if you want to round a double to the nearest int, rather than floor or trunc, use `lrint(x)`

or `(int)nearbyint(x)`

, which can inline to an instruction that uses the current FP rounding mode, which (unless you changed it) will be round-to-nearest (even as tiebreak). See this answer for how it compiles for x86-64 and AArch64.)

**GCC's back-end doesn't optimize away floor** (with either front-end language), `-msse4`

just makes it cheap enough for the throughput bottleneck of `sqrtsd`

to hide its cost in your C benchmark. Specifically, we get

```
# gcc -O2 -fno-math-errno -msse4 with floor() still in the source.
sqrtsd xmm0, xmm0
roundsd xmm0, xmm0, 9 # floor separately, result as a double
cvttsd2si eax, xmm0 # convert (with Truncation) to signed int
```

Even without SSE4, GFortran chooses to use a flooring-conversion to int (which only has to work for the range of `int`

, not for doubles outside that range, which is what GCC's code was doing manually without `-msse4`

):

```
# GFortran -O2 -msse4 # with floor() # chooses not to use SSE4
sqrtsd xmm0, xmm0
cvttsd2si eax, xmm0 # eax = int trunc(sqrt result)
cvtsi2sd xmm1, eax # convert back to double
ucomisd xmm0, xmm1 # compare, setting CF if truncation rounded *up*
sbb eax, 0 # eax -= CF
```

Fun fact: this code avoids checking for "unordered" (PF=1) in the `ucomisd`

FLAGS result. CF = 1 for that case, but apparently gfortran doesn't care that it will make the result 0x7FFFFFFF instead of 0x80000000.

`gcc`

could have done this for C, since the behaviour is undefined if the double->int conversion result doesn't fit in an int. (Fun fact, negative double -> unsigned is also UB for that reason; the modular range-reduction rule is only for wide integral types->unsigned.) So this is a gcc missed optimization bug for C without SSE4.

When SSE4 is available, it's better to use `roundsd`

before conversion (in the general case where floor can't just be optimized away). Round-trip conversion to integer and back is 12 cycle latency on Skylake, so an extra maybe 7 vs. just one convert, plus ucomisd + sbb latency. vs. 8 cycles for `roundsd`

. And `roundsd`

is fewer total uops (https://uops.info). So this is a missed optimization for `gfortran -msse4`

which continues to use its double->int->double compare / sbb trick for floor-conversion.

## Optimizing the source: remove the `floor`

C (and Fortran) FP -> int conversion truncates (rounds towards `0.0`

) by default. For non-negative integers, this is equivalent to `floor`

, so it's redundant. Since compilers don't realize that and/or don't take advantage of the fact that a `sqrt`

result is non-negative (or NaN), we can remove it ourselves:

```
#include <math.h>
int int_sqrt_c(int x){
return sqrt(x - 1.0);
//return floor(sqrt(x - 1.0));
}
```

I also simplified your C to take/return an int, instead of via pointers.
https://godbolt.org/z/4zWeaej9T

```
int_sqrt_c(int):
pxor xmm0, xmm0
cvtsi2sd xmm0, edi # int -> double
subsd xmm0, QWORD PTR .LC0[rip]
sqrtsd xmm0, xmm0
cvttsd2si eax, xmm0 # truncating double -> int
ret
```

Exact same difference for the Fortan code, https://godbolt.org/z/EhbTjhGen - removing `floor`

removes the useless instructions, leaving just `cvttsd2si`

.

`roundsd`

costs 2 uops and has 8 cycle latency on Skylake (like a chain of two additions) https://uops.info/, so avoiding it takes out a decent fraction of the total latency from x -> retval, and of the front-end throughput cost.

(Your throughput benchmark will bottleneck on the *back*-end throughput of `sqrtsd`

, e.g. one per 4.5 cycles on Skylake, and OoO exec hides the latency, so your current test setup probably won't be able to measure the difference.)

`errno`

for floating-point computations (despite this not being required by the C langauge), and compatibility with x86 machines that don't have any better SSE instructions than SSE2. If you want decent code generation, add`-fno-math-errno -msse4`

to the compiler flags – EOF Apr 11 at 15:38